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姓名: 刘通 性别:
职称: 特聘副研究员 学历: 博士
电话: 传真: 010-62010846
Email: liutong[a]mail.iggcas.ac.cn 邮编: 100029
地址: 北京朝阳区北土城西路19号,中科院地质与地球物理研究所
更多信息:

English岩石圈演化与环境演变全国重点实验室岩石圈演化学科中心 大洋岩石圈演化学科组
 
简历:

  刘通,男,特聘副研究员,1987年出生于河北省石家庄晋州市。主要从事蛇绿岩成因与大洋岩石圈演化、特提斯地球动力学、大洋岩石圈的资源环境效应等方面的岩浆岩岩石学与地幔地球化学研究,研究对象为西藏蛇绿岩与现今大洋岩石。主要学术成果包括:1)厘定了西藏日喀则蛇绿岩的超慢速扩张脊成因,建立了蛇绿岩与超慢速洋脊对比研究范式,定义了蛇绿岩新成因类型,发展了超慢速洋脊的俯冲-增生效应;2)通过Re-Os和Lu-Hf同位素研究,在新特提斯缝合带代表性蛇绿岩中识别了古老地幔组分,提出新特提斯软流圈的高度不均一性与大洋壳-幔解耦特征;3)在西藏蛇绿岩中识别天然氢气流体包裹体,建立了蛇纹石化相关天然氢气的“源”与“汇”之间的内在联系,为天然氢气的勘探提供了新启示。
  迄今总共发表论文55篇,其中以第一/通讯作者身份在GCA、SciB、CMP、G-Cubed、CG和中国科学等国内外地学主流SCI期刊上发表论文17篇。担任《Science Bulletin》、《科学通报》、《地质通报》等期刊青年编委或青年副主编,中国矿物岩石地球化学学会青年工作委员会委员;主持国家基金委面上项目、青年项目(C类)、研究所重点部署项目子课题、国家重点实验室开放课题等项目。

学习和工作经历:

  • 2011年本科毕业于长安大学
  • 2014年硕士毕业于中国地质大学(北京),中国地质科学院地质研究所联合培养
  • 2017年博士毕业于中国科学院地质与地球物理研究所
  • 2017年6月-2022年1月于中国科学院地质与地球物理研究所从事博士后研究工作
  • 2019年5-6月赴美国伍兹霍尔海洋研究所(WHOI)访问
  • 2022年1月起任中国科学院地质与地球物理研究所特聘副研究员
  • 2025年7月-2026年1月公派赴德国明斯特大学访问

学术任职:

  • 《Science Bulletin》&《科学通报》青年编委(2026.3-2027.3)
  • 《地质通报》青年编委(2023.7-2026.6)、青年副主编(2024.4-2026.6)
  • 中国矿物岩石地球化学学会青年工作委员会委员(2025-2029)
 
研究方向:
  1. 蛇绿岩成因与大洋岩石圈演化
  2. 特提斯地球动力学
  3. 地幔地球化学
  4. 洋中脊碳通量
  5. 天然氢气成因与勘探
 
学科类别:
岩浆岩岩石学、地幔地球化学
 
职务:
 
社会任职:
 
获奖及荣誉:
  1. 2020年中国科学院地质与地球物理研究所年度优秀科技成果(第四完成人)
  2. 2016年中国科学院地质与地球物理研究所年度优秀科技成果(第四完成人)
 
承担科研项目情况:
  1. 国家自然科学基金,面上项目,42572048,2026.1-2029.12,主持
  2. 中国科学院基础与交叉前沿科研先导专项(B类),项目子课题,XDB0710102,2023.12-2028.11,参与兼项目联系人
  3. 国家自然科学基金特提斯地球动力系统重大研究计划,集成项目(二期),92355301,2024.1-2025.12,参与
  4. 地质地球所重点部署项目,子课题,IGGCAS-202202,2023.1-2025.12,主持(co-chief)
  5. 第二次青藏高原综合科学考察研究,子专题,2019QZKK0801,2019.11-2024.10,参与
  6. 国家自然科学基金,青年项目(C类),41802062,2019.01-2021.12,主持
  7. 岩石圈演化国家重点实验室,开放课题,201707,2018.01-2019.12,主持


指导研究生情况:
  研究生招生:常年招收热爱地质学、岩浆岩岩石学、地幔地球化学的硕士研究生,有意读博者可与其他老师共同指导。如有必要,研究生期间鼓励与国外研究团队深入合作,赴国外交流学习。
  近期,招生方向主要涉及:大洋岩石的岩石学和地球化学、基于西藏蛇绿岩开展的碳循环和碳吸收等。
  目前已毕业博士研究生1名(共同指导,现为崂山实验室博士后)、在读博士研究生1名。
 
代表论著:

Google Scholar     ResearchGate

第一作者或通讯作者:

  1. Liu, T.*, Hu, Y.Q., Liu, C.Z.*, Zhang, C., Fei, C., Wu, F.Y., 2026. The Earth’s mantle fuels our future by hosting and emanating natural hydrogen. Science Bulletin. https://doi.org/10.1016/j.scib.2026.01.026.
  2. Liu, T.*, Liu, C.Z.*, Zhang, C., Zhang, Z., Zhang, Z.Y., Zhang, W.Q., Xu, Y., Ji, W.B., Wu, F.Y., 2026. Paradigm shift in understanding the Yarlung-Tsangpo ophiolites: Insights from comparisons with ultraslow-spreading ocean ridges. Ofioliti. https://doi.org/10.4454/ofioliti.v51i2.581.
  3. Zhang, Z., Liu, T.*, Liu, C.Z., Zhang, C., Tribuzio, R., Song, D.F., Wu, F.Y., 2026. Subduction-accretion of sub-ridge mantle in the south Tibetan mélange zone. Contributions to Mineralogy and Petrology, 181, 15. https://doi.org/10.1007/s00410-026-02298-w .
  4. Liu, T.*, Liu, C.Z., Zhang, Z.Y., Zhang, W.Q., Ji, W.B., Zhang, C., Mitchell, R.N., 2024. Dynamics of the oceanic dike–gabbro transition revealed by petrology and geochemistry of the Yunzhug ophiolite, central Tibet. Contributions to Mineralogy and Petrology, 179, 53. https://doi.org/10.1007/s00410-024-02135-y.
  5. Liu, T.*, Liu, C.Z., Wu, F.Y., Topuz, G., Wan, B., Wang, J.M., Chen, G., 2024. Detachment fault‐hosted subduction re-initiation of the (ultra)slow‐spreading western Neo‐Tethys in the Jurassic. Geochemistry, Geophysics, Geosystems, 25, e2023GC011173. https://doi.org/10.1029/2023GC011173 .
  6. Liu, T.*, Liu, C.Z., Wu, F.Y., Ji, W.B., Zhang, C., Zhang, W.Q., Zhang, Z.Y., 2023. Timing and mechanism of opening the Neo-Tethys Ocean: Constraints from mélanges in the Yarlung Zangbo suture zone. Science China Earth Sciences, 66 (12), 2807–2826. https://doi.org/10.1007/s11430-023-1175-5. [刘通*, 刘传周, 吴福元, 冀文斌, 张畅, 张维骐, 张振宇, 2023. 新特提斯洋的打开时间和机制: 雅江缝合带混杂岩的约束. 中国科学: 地球科学, 53 (12), 2846–2867. https://doi.org/10.1360/SSTe-2023-0049.]
  7. Zhang, Z., Liu, T.*, Liu, C.Z., Jung, S., Jung, H., 2023. The water-poor and reduced mantle beneath the Neo-Tethys Ocean: Tectonic setting of the western Yarlung-Tsangpo ophiolites. Lithos, 456–457, 107326. https://doi.org/10.1016/j.lithos.2023.107326 .
  8. Zhang, Z., Liu, T.*, Liu, C.Z., Zhang, C., Wu, F.Y., 2022. The heterogeneous mantle massif in south Tibetan ophiolites and its implication for the tectonic evolution of Neo-Tethys. Lithos, 424–425, 106761. https://doi.org/10.1016/j.lithos.2022.106761.
  9. Liu, T.* Liu, C.Z.*, Chen, Y., Guo, S., Sein, K., Dong, X.T., 2022. Petrology and geochemistry of ultramafic rocks in the Mogok belt, Myanmar: Cumulates from high-pressure crystallization of hydrous arc melts. Geological Journal, 57, 886-905.
  10. Liu, T.* Wu, F.Y., Liu, C.Z., Zhu, D.C., Lin, Y.Z., 2021. Recycling of ancient sub-oceanic mantle in the Neo-Tethyan asthenosphere: Evidence from major and trace elements and Hf–Os isotopes of the Kop Mountain ophiolite, NE Turkey. Geochimica et Cosmochimica Acta, 311, 43–58.
  11. Liu, T.* Dick, H.J.B., Liu, C.Z., Wu, F.Y., Ji, W.B., Zhang, C., Zhang, W.Q., Zhang, Z.Y., Lin, Y.Z., Zhang, Z., 2021. Tectonic controls on block rotation and sheeted sill emplacement in the Xigaze ophiolite (Tibet): The construction mode of slow-spreading and ultraslow-spreading oceanic crusts. Geochemistry, Geophysics, Geosystems, 22, e2020GC009297.
  12. Liu, T.* Liu, C.Z.*, Wu, F.Y., Dick, H.J.B., Ji, W.B., Zhang, C., Zhang, W.Q., Zhang, Z.Y., Xu, Y., 2021. The Xigaze ophiolite: fossil ultraslow-spreading ocean lithosphere in the Tibetan Plateau. Journal of the Geological Society, 178, jgs2020-208.
  13. Liu, T.* Wu, F.Y., Liu, C.Z., Eyuboglu, Y., Zhu, D.C., Zhang, C., Ji, W.B., Xu, Y., Zhang, Z.Y., 2020. Testing oceanic crust–mantle decoupling by Sr–Nd–Hf–Os isotopes of Neo-Tethyan ophiolites. Lithos, 376–377, 105757.
  14. Liu, T.* Wu, F.Y., Liu, C.Z., Zhang, C., Ji, W.B., Xu, Y. 2019. Reconsideration of Neo-Tethys evolution constrained from the nature of the Dazhuqu ophiolitic mantle, southern Tibet. Contributions to Mineralogy and Petrology, 174: 23.
  15. Liu, T.* Wu, F.Y., Liu, C.Z., Tribuzio, R., Ji, W.B., Zhang, C., Xu, Y., Zhang, W.Q. 2018. Variably evolved gabbroic intrusions within the Xigaze ophiolite (Tibet): new insights into the origin of ophiolite diversity. Contributions to Mineralogy and Petrology, 173: 91.
  16. Liu, T.* Wu, F.Y., Zhang, L.L., Zhai, Q.G., Liu, C.Z., Ji, W.B., Zhang, C., Xu, Y. 2016. Zircon U-Pb geochronological constraints on rapid exhumation of the mantle peridotite of the Xigaze ophiolite, southern Tibet. Chemical Geology, 443, 67–86.
  17. Liu, T., Zhai, Q.G.*, Wang, J., Bao, P.S., Qiangba, Z.X., Tang, S.H., Tang, Y. 2016. Tectonic significance of the Dongqiao ophiolite in the north-central Tibetan plateau: Evidence from zircon dating, petrological, geochemical and Sr–Nd–Hf isotopic characterization. Journal of Asian Earth Sciences, 116, 139–154.
  18. 刘通, 翟庆国*, 王军, 苏犁, 康珍, 索朗次列. 2013. 藏北羌塘盆地基底高级变质岩LA-ICP-MS锆石U-Pb年龄及其地质意义. 地质通报, 32 (11), 1691–1703.

合作文章:

  1. Mariani, D., Tribuzio, R., Liu, T., Wu, F.Y., Zanetti, A., 2026. Underplating of H2O-rich magmas in post-collisional tectonic settings. Geochimica et Cosmochimica Acta, 414, 295-314. https://doi.org/10.1016/j.gca.2025.12.018 .
  2. Zhang, Z.Y., Liu, C.Z., Liang, Y., Liu, T., Zhang, C., Liu, B.D., 2026. Mantle heterogeneity and complicated melt migration revealed by chemical gradients across the dunite-harzburgite sequence in the Zedong ophiolite, South Tibet. Contributions to Mineralogy and Petrology, 2026, 181, 5. https://doi.org/10.1007/s00410-025-02287-5 .
  3. Zhang, W.Q., Liu, C.Z., Liu, T., Li, X.N., Zhang, C., Zhang, Z.Y., Zhang, Z., Lin, Y.Z., 2025. Intra-oceanic arc subduction within the Meso-Tethys Ocean constrained by arc crust remnants in the Lagkorco ophiolite, Central Tibet. Lithos, 518-519, 108303, https://doi.org/10.1016/j.lithos.2025.108303 .
  4. Zhang, Z., Liu, C.Z., Jung, H., Liu, T., Zhang, C., Cao, Y., Jung, S., Zhang, W.Q., Lin, Y.Z., Li, X.N., 2025. Multi-Stage Evolution of Deformed Peridotites in the Yarlung-Tsangpo Suture Zone: A Link to Mantle Shear Initiation at H2O-Deficient Ultraslow-Spreading Ridges. Journal of Petrology, 66 (9), egaf073, https://doi.org/10.1093/petrology/egaf073
  5. Zhang, C., Liu, C.Z., Liu, T., Ji, W.B., Zhang, Z.Y., Wu, F.Y., 2025. Petrogenesis of mafic to intermediate rocks within the crustal sequence of the Luqu ophiolite in the Yarlung-Tsangpo suture zone, southern Tibet and implications for the Neo-Tethys evolution. Journal of Asian Earth Sciences, 291, 106696.
  6. Zhu, J.N., Liu, C.Z., Zhang, W.Q., Liu, T., Zhang, C., Li, X.N., Zhang, Z.Y., 2025. Recycling ancient refractory peridotites causing the crust-mantle decoupling of the Xigaze ophiolite (South Tibet): New constraints from the Buma mantle massif. Lithos, 508–509, 108090.
  7. Li, X.N., Zhang, W.Q., Liu, T., Zhang, C., Lin, Y.Z., Zhang, Z., Zhu, J.N., Li, H.Y., Liu, C.Z., 2025. Mantle evolution beneath a back-arc basin: Highly siderophile elements and Os isotope of Dongco ophiolitic peridotites, Tibet. Chemical Geology, 683, 122757.
  8. Lin, Y.Z., Liu, C.Z., Zhang, W.Q., Zhang, Z.Y., Zhang, C., Liu, T., 2025. Recycling of subduction-modified refractory mantle beneath the Marion Rise, Southwest Indian Ridge. Contributions to Mineralogy and Petrology, 180:17. https://doi.org/10.1007/s00410-025-02205-9.
  9. Zhang, W.Q., Liu, C.Z., Liu, T., Zhang, C., Li, X.N., Zhang, Z.Y., Zhang, Z., Lin, Y.Z., 2025. Remnants of a Jurassic marginal sea plate in the Meso-Tethyan Ocean revealed by multi-stage magmatism in the Lagkorco ophiolite, Central Tibet. Lithos, 494–495, 107895. https://doi.org/10.1016/j.lithos.2024.107895.
  10. Xu, Y., Liu, C.Z., Zhang, C., Liu, T., 2025. Re-Os isotopic evidence for ancient melt depletion in refertilized Neo-Tethyan suboceanic mantle domain. Chemical Geology, 673, 122520. https://doi.org/10.1016/j.chemgeo.2024.122520  .
  11. Zhang, Z.Y., Liu, C.Z., Liang, Y., Zhang, L.L., Zhang, C., Liu, T., Liu, B.D., Zhang, W.Q., Lin, Y.Z., Ji, W.B., 2024. Petrogenesis of the pyroxenitic Moho transition zone in the Zedong ophiolite, Southeastern Tibet. Lithos, 482–483, 107703. https://doi.org/10.1016/j.lithos.2024.107703  .
  12. Lin, Y.Z., Liu, C.Z., Dick, H.J.B., Mitchell, R.N., Wu, S.T., Liu, T., Zhang, W.Q., Zhang, Z.Y., 2024. Detrital peridotite minerals reveal recycled arc mantle beneath Marion Rise, Southwest Indian Ridge. Terra Nova, 36, 230–238. https://doi.org/10.1111/ter.12702  .
  13. Zhang, Z.Y., Liu, C.Z., Liang, Y., Liu, T., Zhang, C., Liu, B.D., Lin, Y.Z., Zhang, W.Q., Ji, W.B., 2023. Pyroxenite–harzburgite sequences in the Dazhuqu ophiolite (Southern Tibet) formed through hydrous melt infiltration and melt–peridotite reaction. Contributions to Mineralogy and Petrology, 178, 92. https://doi.org/10.1007/s00410-023-02076-y  .
  14. Zhang, C., Liu, C.Z., Ji, W.B., Liu, T., Zhang, Z.Y., Wu, F.Y., 2023. Subduction of solidifying melt lens beneath ultraslow-spreading ridges revealed by (Grt-)amphibolites and dolerites in the Xiugugabu ophiolitic mélange, southwestern Tibet. Lithos, 462–463, 107421. https://doi.org/10.1016/j.lithos.2023.107421  .
  15. Zhang, C., Liu, C.Z., Bénard, A., Müntener, O., Ji, W.B., Liu, T., Zhang, Z.Y., Zhang, W.Q., Wu, F.Y., 2023. Heterogeneous mantle beneath the Neo‑Tethys Ocean revealed by ultramafic rocks from the Xiugugabu Ophiolite in the Yarlung‑Tsangpo Suture Zone, southwestern Tibet. Contributions to Mineralogy and Petrology, 178: 54. https://doi.org/10.1007/s00410-023-02039-3  .
  16. Zhang, C., Liu, C.Z., Liu, T., Ji, W.B., Wu, F.Y., 2023. Generation of ultraslow‑spreading oceanic crust traced by various mafic blocks from ophiolitic mélange in the Xigaze Ophiolites, southern Tibet. Contributions to Mineralogy and Petrology, 178: 55. https://doi.org/10.1007/s00410-023-02040-w  .
  17. Li, X.N., Zhang, W.Q., Liu, T., Zhang, C., Zhang, Z., Lin, Y.Z., Liu, C.Z., 2023. Crustal accretion in a slow-spreading center of Meso-Tethyan Ocean: Constraints from cumulates in the Dongco ophiolite (Central Tibet). Lithos, 446–447, 107144. https://doi.org/10.1016/j.lithos.2023.107144  .
  18. Tribuzio, R., Renna, M.R., Antonicelli, M., Liu, T., Wu, F.Y., Langone, A., 2023. The peridotite-pyroxenite sequence of Rocca d’Argimonia (Ivrea-Verbano Zone, Italy): Evidence for reactive melt flow and slow cooling in the lowermost continental crust. Chemical Geology, 619, 121315. https://doi.org/10.1016/j.chemgeo.2023.121315  .
  19. Zhang, W.Q., Liu, C.Z., Liu, T., Zhang, C., Zhang, Z.Y., Li, X.N., Zhang, Z., Lin, Y.Z., 2022. Multi‑stage melt impregnation and magma–seawater interaction in a slow‑spreading oceanic lithosphere: constraints from cumulates in the Lagkorco ophiolite (central Tibet). Contributions to Mineralogy and Petrology, 177 (11): 109. https://doi.org/10.1007/s00410-022-01976-9.
  20. Liu, Y., Zhang, C.Q., Zhang, D., Liu, T., Qiu, H., Li, Q.L., Li, J.H., 2022. Non-destructive Micro X-ray Fluorescence Quantitative Analysis of Geological Materials. Atomic Spectroscopy, 43, 378-387. https://doi.org/10.46770/AS.2022.112  .
  21. Zhang, Z.Y., Liu, C.Z., Liang, Y., Zhang, C., Liu, T., Zhang, W.Q., Ji, W.B., 2022. Decoupled Trace Element and Isotope Compositions Recorded in Orthopyroxene and Clinopyroxene in Composite Pyroxenite Veins from the Xiugugabu Ophiolite (SW Tibet). Journal of Petrology, 63 (6), egac046. https://doi.org/10.1093/petrology/egac046  .
  22. Zhang, W.Q., Liu, C.Z., Mitchell, R.N., Liu, T., Zhang, C., Zhang, Z.Y., 2022. Extensive melting of ancient depleted oceanic mantle evidenced by decoupled Hf–Nd isotopes in the lowermost oceanic crust. Lithos, 418-419, 106684. https://doi.org/10.1016/j.lithos.2022.106684  .
  23. Liu, C.Z., Wu, F.Y., Liu, T., Zhang, C., Zhang, W.Q., Zhang, Z.Y., Zhang, Z., Wei, W., Lin, Y.Z., 2022. An origin of ultraslow spreading ridges for the Yarlung-Tsangpo ophiolites. Fundamental Research, 2, 74-83.
  24. Zhang, W.Q., Liu, C.Z., Liu, T., Zhang, C., Zhang, Z.Y., 2021. Subduction initiation triggered by accretion of a Jurassic oceanic plateau along the Bangong–Nujiang Suture in central Tibet. Terra Nova, 33, 150-158.
  25. Antonicelli, M., Tribuzio, R., Liu, T., Wu, F.Y., 2020. Contaminating melt flow in magmatic peridotites from the lower continental crust (Rocca d’Argimonia sequence, Ivrea–Verbano Zone). European Journal of Mineralogy, 32, 587–612.
  26. Zhang, C., Liu, C.Z., Ji, W.B., Liu, T., Wu, F.Y., 2020. Heterogeneous sub-ridge mantle of the Neo-Tethys: Constraints from Re-Os isotope and HSE compositions of the Xigaze ophiolites. Lithos, 378–379, 105819.
  27. Yang, J.F., Lu, G., Liu, T., Li, Y., Wang, K., Wang, X.X., Sun, B.L., Faccenda, M., Zhao, L. 2020. Amagmatic subduction produced by mantle serpentinization and oceanic crust delamination. Geophysical Research Letters, 47, e2019GL086257.
  28. Zhang, C., Liu, C.Z., Liu, T., Wu, F.Y. 2020. Evolution of mantle peridotites from the Luobusa ophiolite in the Tibetan Plateau: Sr-Nd-Hf-Os isotope constraints. Lithos, 362–363, 105477.
  29. Ji, W.Q., Wu, F.Y., Liu, X.C., Liu, Z.C., Zhang, C., Liu, T., Wang, J.G., Paterson, S.R. 2020. Pervasive Miocene melting of thickened crust from the Lhasa terrane to Himalaya, southern Tibet and its constraint on generation of Himalayan leucogranite. Geochimica et Cosmochimica Acta, 278, 137-156.
  30. Zhang, C., Liu, C.Z., Xu, Y., Ji, W.B., Wang, J.M., Wu, F.Y., Liu, T., Zhang, Z.Y., Zhang, W.Q. 2019. Subduction re-initiation at dying ridge of Neo-Tethys: Insights from mafic and metamafic rocks in Lhaze ophiolitic mélange, Yarlung-Tsangbo Suture Zone. Earth and Planetary Science Letters, 523, 115707.
  31. 吴福元, 王建刚, 刘传周, 刘通, 张畅, 纪伟强. 2019. 大洋岛弧的前世今生. 岩石学报, 35(01), 1–15.
  32. Zhang, C., Liu, C.Z., Wu, F.Y., Ji, W.B., Liu, T., Xu, Y. 2017. Ultra-refractory mantle domains in the Luqu ophiolite (Tibet): Petrology and tectonic setting. Lithos, 286–287, 252–263.
  33. Zhai, Q.G., Jahn, B.M., Li, X.H., Zhang, R.Y., Li, Q.L., Yang, Y.N., Wang, J., Liu, T., Hu, P.Y., Tang, S.H. 2017. Zircon U–Pb dating of eclogite from the Qiangtang terrane, north central Tibet: a case of metamorphic zircon with magmatic geochemical features. International Journal of Earth Sciences, 106, 1239-1255.
  34. 唐跃, 翟庆国, 刘通, 王军, 胡培远, 强巴扎西, 索朗赤列. 2015. 西藏班戈县达如错花岗斑岩LA-ICP-MS锆石U-Pb年龄、地球化学特征及其地质意义. 地质通报, 34 (10), 1802–1811.

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